System and Method for Communication Among Embedded Devices Using Visual Images

ABSTRACT

A system and method for wireless communication among embedded devices using visual images. More specifically, a signal receiving device uses a visual recording device to locate the signal display screen of a signal transmitting device by employing an alternating image detection method. An image decoder embedded in the signal receiving device decodes the signal received by the visual recording device. In addition, a method is employed for automatically controlling the position and orientation of the signal display device and the visual recording device. Advantageously, communication among the embedded devices can be effectuated without the emission of potentially harmful radiation.

CROSS-REFERENCE TO RELATED APPLICATION

This is a Continuation Application of U.S. application Ser. No.09/640,284 filed on Aug. 16, 2000, the disclosure of which is hereinincorporated by reference in its entirety.

BACKGROUND OF THE INVENTION

1. Technical Field

The present invention relates generally to communications and, morespecifically, to a system and method for wireless communications amongcomputers and other pervasive processing devices.

2. Description of the Related Art

As processing devices become less expensive and more compact, theall-purpose desktop computer is giving way to a new generation ofembedded or “smart” devices such as video phones, interactive kiosks,and embedded household devices such as intelligent refrigerators, smartTVs, and intelligent dishwashers. Embedded devices are devices embeddedwith computing capability, making these devices “intelligent”.

As embedded devices become more widely used, they need to be able tocommunicate and exchange information with each other. For example, avideo phone must be able to transmit and receive information with othervideo phones for effective communication.

Communication between computers is typically trough a communicationnetwork, in which computers are connected to each other or toperipherals by hard wire. This technique has a number of disadvantages.For example, cable connection interfaces such as parallel printer ports,are limited in the distance they can reliably transfer data. Inaddition, coaxial cables, which are used for longer distance hard wirecommunications, require a relatively expensive terminal interface andtherefore are not widely used for connecting peripheral devices tocomputers. Moreover, when computers are hard-wired, any movement orchange in the physical locations of the computers requires rewiring andreinstallation.

The prior art teaches communication between embedded devices similar tothe communication between computers, as well as existing wirelesscommunication techniques. For example, U.S. Pat. No. 5,613,070discloses, a system for providing improved communication to data andcomputer communications network using parallel and serial communicationbuses and master and local routers. Communication through said networkincludes use of a master system board with a plurality of subsystemboards.

U.S. Pat. No. 5,369,755 discloses a computer communication bus systemusing multiple content induced transaction overlap (CITO) communicationchannels having a plurality of data transmission lines and a pluralityof transmission nodes connected to the communication bus. Eachtransmission node has a data source providing multi-bit data to betransmitted on the communication bus, a plurality of data transformersfor encoding or transforming the multi-bit data into different multi-bitencoded data formats, and a plurality of CITO transmitters fortransmitting the a content induced transaction overlap (CITO) protocol.Using the CITO protocol, the CITO transmitters transmit the same data oneach of the transmission lines in a different order.

Another form of communication between embedded devices is wirelesscommunication. Existing wireless technology includes microwave systems,infrared laser systems, or spread spectrum. However, all theseapproaches have various disadvantages, including health concerns due toradiation emission and interference of signals.

Microwave is the oldest technology for wireless communications. Fordecades, most major telecommunications companies have used microwavesystems within their networks for transmission of telephonecommunications, data and video. However, this form of wirelesscommunication has significant disadvantages. For example, microwavesignals travel in straight lines and do not readily diffract aroundbarriers such as large man-made structures, hills and mountains. Someattenuation occurs when microwave energy passes through trees and framehouses. In addition, exposure to microwaves (a form of radiation) posesa health hazard and can cause nerve, fetal and DNA damage, cataracts,behavioral disturbances, changes to blood chemistry and impaired immunedefense.

For example, U.S. Pat. No. 4,933,682 discloses a point to pointmicrowave communication service antenna pattern with anull in aninterfering direction that includes a microwave antenna system at eachpoint directed at the other point, the radiation pattern of the antennasystem at at least one point has a substantial null in the direction ofan antenna of another microwave communication service to avoid anexchange of signals with the other service, the antenna system providedat said one point includes two antenna elements having substantiallyequal directional radiation patterns, so oriented and spaced apart adistance that is at least several wave length of the operating frequencyof the elements so that the radiation patterns of the elements overlapproducing a net radiation pattern that results from interference of thepatterns and the net pattern has a substantial lobe in the direction ofthe other point of said service and a substantial null in the directionof an antenna of the other microwave communication service.

Another form of wireless communications is spread spectrum. Spreadspectrum uses de-restricted radio frequencies and comes in two forms:direct sequencing and frequency hopping. Direct sequencing involves theuse of a constant frequency for direct transmission. However, this formof spread spectrum is subject to problems such as catastrophicinterference since it uses a signal whose frequency is constant.Catastrophic interference occurs when another signal is transmitted on,or very near, the frequency of the desired signal. In addition, aconstant-frequency signal is easy to intercept, and is therefore notsuited to applications in which information must be kept confidentialbetween the transmitting and receiving parties.

Frequency hopping transmissions seek open frequencies and hop fromfrequency to frequency at split second intervals according to a specificand complicated mathematical function. Although this form of spreadspectrum is more secure than direct sequencing, transmissions are secureonly if the mathematical function is kept out of the hands ofunauthorized people or entities. In addition, radio frequency emissionis a type of electromagnetic energy or radiation, and thus is a possiblehealth risk and cause for concern due to radiation exposure.

U.S. Pat. No. 5,854,985 discloses, an adaptive omni-modal radioapparatus and method for describing a frequency and protocol agilewireless communication product, and chipset for forming the same,including a frequency agile transceiver, a digital interface circuit forinterconnecting the radio transceiver with external devices, protocolagile operating circuit for operating the radio transceiver inaccordance with one of the transmission protocols as determined by aprotocol signal and an adaptive control circuit for accessing a selectedwireless communication network and for generating the frequency controlsignal and the protocol control signal in response to a user definedcriteria.

U.S. Pat. No. 5,761,621 discloses a network and method of operating anetwork of wireless service providers adapted to interact with aplurality of omni-modal wireless products within a given geographic areain a manner to permit the wireless service providers to “borrow” radiofrequencies from other wireless service providers within the samegeographic region.

Another form of wireless communication is the infrared lasercommunication system, which is used in thousands of installationsworld-wide for cable-free transmission of data, voice and video atspeeds from T-1 through 622 Mbps. These systems can provide atransparent and cost effective connection between buildings at distancesup to 6000 meters (3.69). These free-space, optical laser communicationssystems are wireless connections through the atmosphere communicatingvia electromagnetic radiation. Infrared laser systems work basically thesame as fiber optic cable except the beam is transmitted through openspace rather than glass fiber. The systems operate by taking a standarddata or telecommunications signal, converting it into a digital formatand transmitting it through free space. Two parallel beams are used, onefor transmission and one for reception. The carrier used for thetransmission of this signal is infrared and is generated by either ahigh power LED or a laser diode. The disadvantage of this form ofwireless communication, however, is the possible health risk due toemission of radiation, especially in enclosed spaces where there arenumerous devices communicating with each other via infrared, which havefrequencies higher than those of microwaves.

U.S. Pat. No. 5,247,380 discloses an infrared data communicationsnetwork in which groups of personal computers and associated peripheralsmay communicate by infrared signals with each other. The system utilizesa error correction and a packet switched protocol which allows anyterminal to select communications with any other terminal or terminalswithout degradation of the error rate. Error free transmission ismaintained by means of error correcting encoding and a handshakeprotocol. The packet switched protocol permits any terminal to functionas a store and forward repeater thus making the system less susceptibleto beam blockage.

As embedded devices become more commonplace, homes and offices arebecoming occupied by greater numbers of various intelligent applianceswhich need to communicate with each other. Using current wirelesscommunication techniques may be a health hazard because of the highoutput of emitting rays in relatively small enclosed spaces. In largeramounts, microwave and spread spectrum radio waves in enclosed spacescan interfere with each other. Accordingly, an efficient, accurate andnon-emitting wireless communication technique which allows embeddeddevices to communicate with each other is highly desirable.

SUMMARY OF THE INVENTION

The present invention is directed to a system and method for wirelesscommunication among embedded devices using visual images. In one aspectof the present invention, a communication system is provided comprisinga signal transmitting device having a sending CPU and a sending memory;a generated signal template for encoding a signal pattern to betransmitted; a signal display for displaying the signal pattern encodedby said generated signal template; a signal display controller forcontrolling position and orientation of said signal display; a signalreceiving device for communicating with said signal transmitting devicehaving a receiving memory and a receiving CPU; a visual recording devicefor sensing the signal pattern of the signal display; an image decoderfor decoding the signal pattern; and a visual recording devicecontroller for automatically controlling the orientation and zoom ofsaid visual recording device, wherein communication between said signaltransmitting device and said signal receiving device is established bythe visual recording device detecting and decoding visual imagesdisplayed by the signal display. More specifically, a generated signaltemplate embedded in the signal transmitting device encodes visualsignal patterns to be transmitted, and an image deocder embedded in thesignal receiving device decodes the signal received by the visualrecording devices.

In another aspect of the present invention, a method of visualcommunication between a signal transmitting device and a signalreceiving device is provided comprising the steps of adjusting a signaldisplay of said signal transmitting device and a visual recording deviceof said signal receiving device and using an alternating display processto establish a visual connection between said signal display and saidvisual recording device; encoding a signal pattern using a generatedsignal template of said signal transmitting device; visuallytransmitting the signal pattern through free space from the signaldisplay of said signal transmitting device; receiving an image of thesignal pattern using the visual recording device of said signalreceiving device; and decoding the signal pattern using an image decoderof the signal receiving device.

In yet another aspect of the present invention, a sending controllerautomatically controls the position and orientation of the signaldisplay such that the signal display establishes a visual connectionwith the visual recording device.

In yet another aspect of the present invention, a receiving devicecontroller automatically controls the orientation and zoom of the visualrecording device. More specifically, the pan, tilt and zoom of thevisual recording device is automatically adjusted to view the signaldisplay of the signal transmitting device.

In yet another aspect of the present invention, the signal receivingdevice locates the signal display of the signal transmitting device bydetecting changing images displayed by the signal display. Morespecifically, the signal receiving device asks the signal transmittingdevice to alternate its signal display within a certain period of time.The signal receiving device then locates the signal display bydetermining the largest area of an alternating image.

An object of the invention is an improved system and method for wirelesscommunication among embedded devices without harmful radiation.

These and other aspects, features and advantages of the presentinvention will be described or become apparent from the followingdetailed description of the preferred embodiments, which is to be readin connection with the accompanying drawings.

BRIEF DESCRIPTION OF THE FIGURES

FIG. 1 is a block diagram of a system architecture for providingcommunication between a signal transmitting device and a signalreceiving device according to an embodiment of the present invention.

FIG. 2 is a flow chart of a communication process for signaltransmitting device T (170) according to an aspect of the presentinvention.

FIG. 3 is a flow chart of a communication process for signal receivingdevice R (175) according to an aspect of the present invention.

FIG. 4 is a flow chart depicting an example of the process of step 201of FIG. 2 in which the position and orientation of T's signal display isdetermined according to an aspect of the present invention.

FIG. 4A is a flow chart depicting an example of the process of step 455of FIG. 4 in which all possible candidate directions are generated.

FIG. 5 is a flow chart depicting an example of the process of step 301of FIG. 3 in which the position, orientation and zoom of the visualrecording device of device R is determined according to an aspect of thepresent invention.

FIG. 6 is a flow chart depicting an example of the process of step 301in which the pan, tilt, and zoom of the visual recording device ofdevice R is automatically adjusted to view the signal display of T.

FIG. 7 is a flow chart depicting an example of the process of step 671of FIG. 6 in which a next viewing direction and angle size for device Ris selected.

FIG. 8 is a flow chart depicting an example of the process of step 755of FIG. 7 in which a viewing angle size for the visual recording deviceof device R is automatically selected.

FIG. 9 is a flow chart depicting an example of the process of step 775of FIG. 7 in which a viewing direction for a given angle size of thevisual recording device of device R is automatically selected accordingto an aspect of the present invention.

FIG. 10 is a flow chart depicting an example of the process of step 657of FIG. 6 in which changing images are detected to find the signaldisplay of device T according to an aspect of the present invention.

FIG. 11 is a flow chart depicting an example of an encoding strategydetermination process of step 255 in FIG. 2 in which device Tcommunicates with device R to determine T's signal encoding mechanismaccording to one aspect of the present invention.

FIG. 12 is an exemplary illustration of the encoding strategy of FIG.11.

FIG. 13 is a flow chart depicting an example of the process of step 355of FIG. 3 for building a position and radius size look-up tableaccording to one aspect of the present invention.

FIG. 14 is an exemplary illustration of a position and radius sizelook-up table of FIG. 13 according to an aspect of the presentinvention.

FIG. 15 is a flow chart depicting an example of a visual communicationprocess for device T and device R according to an aspect of the presentinvention.

FIG. 16 is a flow chart depicting an example of a visual communicationsignal decoding process for device R of step 1555 of FIG. 15 accordingto an aspect of the present invention.

FIG. 17 is an exemplary illustration of step 1655 of

FIG. 16 according to an aspect of the present invention.

FIG. 18 is an exemplary illustration of step 1675 of

FIG. 16 according to an aspect of the present invention.

DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS

It is to be understood that the exemplary system modules and methodsteps described herein may be implemented in various forms of hardware,software, firmware, special purpose processors, or a combinationthereof. Preferably, the present invention is implemented in software asan application program tangibly embodied on one or more program storagedevices. The application program may be executed by any machine, deviceor platform comprising suitable architecture. It is to be furtherunderstood that, because some of the constituent system modules andmethod steps depicted in the accompanying Figures are preferablyimplemented in software, the actual connections between the systemcomponents (or the process steps) may differ depending upon the mannerin which the present invention is programmed. Given the teachingsherein, one of ordinary skill in the related art will be able tocontemplate these and similar implementations or configurations of thepresent invention.

Referring now to FIG. 1, a block diagram illustrates a systemarchitecture for providing communication between a signal transmittingdevice and a signal receiving device according to an embodiment of thepresent invention. Signal transmitting device T 170 includes a sendingCPU 151 and a signal display 150 that can display various patternscorresponding to signals to be transmitted to signal receiving device R175. Generated signal template 155 generates these signal patterns to betransmitted, which are stored in sending memory 160. Sending controller157 controls the position and orientation of the signal display 150.

When transmission of the signal takes place, visual recording device105, which includes a receiving CPU 125, takes a picture of an image 152displayed by signal display 150. Receiving controller 117 controls theposition and orientation of the visual recording device 105. The sendingcontroller 157 and the receiving controller 117 enable adjustments to bemade so that a visual connection can be established between the visualrecording device and the signal display; in other words, so that thevisual recording device and the signal display can locate each other.Frame grabber 117 then sends the image to receiving memory 145, where itis stored as a stored image 135. An image analysis process is thencommenced by image decoder 115 in which the signal is decoded.

FIG. 2 is a flow chart depicting an example of a communication processfor signal transmitting device T in which T communicates with Raccording to one aspect of the present invention. This process includesthe step of device T communicating with device R to determine theposition and orientation of device T's signal display (201). Thecommunication process of step 201 can be executed using existingwireless technology, or can be done manually by a person. In step 255,device T communicates with device R to determine T's signal encodingstrategy. After device T has determined the position and orientation ofits signal display and its signal encoding mechanism, it then performs avisual communication process 275, in which a signal is transmitted fromT to R.

FIG. 3 is a flow chart depicting an example of a communication processfor signal receiving device R in which R communicates with T accordingto one aspect of the present invention. This process includes the stepof device R communicating with device T to determine the position,orientation and zoom of device R's visual recording device (301). Thecommunication process of step 301 can be carried out using existingwireless communication technology or can be done manually by a person.In step 355, device R communicates with device T to determine R's signaldecoding mechanism. Following these steps, device R performs a visualcommunication process (375) with device T, in which R receives anddecodes a signal from T.

The flow diagram of FIG. 4 depicts an example of the process of step 201for determining position and orientation of the signal display 150 of Tto enable a communication channel with device R according to an aspectof the present invention. Initially, the position of the signaltransmitting device T is determined such that there are no occlusions(i.e., physical obstacles) between the signal transmitting device T andthe signal receiving device R (step 401). Next, the orientation of thesignal display 150 of the signal transmitting device T is adjusted sothat the signal display of signal transmitting device T almost directlyfaces signal receiving R (step 405). Various orientations are tried eachtime. A next candidate display orientation of the signal display ofdevice T is then created (step 455). After a display orientation isselected, signal display 150 alternates its display, for example,between black and white and asks device R to detect the area ofalternating display or “changing blob”; at the same time, device R willdetect the area of the alternating display based on the images taken byits visual recording device (step 465).

The orientation of the signal display T when the area of the alternatingdisplay is largest is recorded by device R.(step 475). It is thenascertained whether enough orientations have been tried (step 485). Ifnot, go back to step 455 and repeat the process thereon. If enoughorientations have been tried, the orientation of the signal transmittingdevice T where the area calculated by the signal receiving device waslargest is recorded by T (step 495). This is the orientation in whichthe signal display of T is perpendicular to the line connecting thecenter of the signal display of T and the center of the visual recordingdevice of the signal receiving device R.

An example of a detailed description depicting the process of step 455is illustrated in FIG. 4A. FIG. 4A illustrates the process of generatingall possible candidate directions (each candidate direction is thentried individually by the person depicted in FIG. 4 above). For example,if the orientation of the signal display of T is <p*,t*> in step 405,all candidate directions are given by the exemplary process described asfollows. (It is to be appreciated that the direction <p*,t*> can also bea candidate direction). First, the orientations of p* and t* are changedby 15 degrees; thus Δp=−15*, Δt=−15* (step 403). Candidate directionsare therefore represented by <p*+Δp, t*+Δt> (step 407). Next, Δp isincreased in increments of 1 degree (step 457). It is then ascertainedwhether Δp>15* (step 467). If no, then the process from step 407 isrepeated. If yes, then Δp=0 (step 477). Next, Δt is increased inincrements of 1 degree (step 487). After each increase, it isascertained whether Δt>15* (step 497). If no, then the process from step407 is repeated. If yes, then all possible candidates have been created,and the process proceeds to step 495 of FIG. 4.

Referring now to FIG. 5, a flow chart depicts an example of the processof step 301 of FIG. 3 in which the position, orientation and zoom of thevisual recording device of device R is determined according to an aspectof the present invention. Initially, the position of device R isdetermined such that there is no object occluding device R and device T(step 501). Next, the direction of the visual recording device of thesignal receiving device R is adjusted such that it points to the centerof the signal display of device T, and the zoom of the visual recordingdevice is adjusted such that it gets a complete view of the signaltransmitting device T (step 515), “complete view” here can mean a viewthat is not necessarily centered. The direction of the visual recordingdevice is re-adjusted so that the center of the signal display of deviceT appears at the center of the image taken by the visual recordingdevice of R (step 555). The zoom of the visual recording device is thenre-adjusted so that an adequately sized view of the signal display ofdevice T is attained (“adequately sized” or “adequate size” hereinmeaning that encoded information shown by the signal display isdisplayed at a size large enough to be analyzed by the visual recordingdevice R).

Referring now to FIG. 6 a flow chart depicts an example of the processof step 301 in which the pan, tilt and zoom of the visual recordingdevice of R is automatically adjusted to view the signal display of T inan aspect of the present invention.

Initially, device R (175) sends signals to device T (170) asking T toalternate the color of T's signal display (150), for example, betweenblack and white within a certain period of time, for example, every 5seconds (step 601). Next, the angle of the visual recording device of Ris set to be a first visual angle size (615). In addition, the viewingdirection of the visual recording device of R is set to be the firstdirection (step 655). The images grabbed from the visual recordingdevice of R are then examined to identify the alternating display ofsignal device T, or “changing blob” within the images (step 657). DeviceR then determines whether the alternating display of device T can befound from the images (step 659).

If the signal display of device T cannot be found, a new viewing anglesize and viewing direction can be selected for the visual recordingdevice of R (step 671). It is then determined whether any occlusions aredetected (step 677). If an occlusion is detected, step 501 is repeated.If there are no occlusions, then the process goes back to step 657 andrepeats the steps thereon.

If the signal display of device T is found, the viewing direction of thevisual recording device of R can be adjusted so that the center of thesignal display of T is at the center of the image grabbed from thevisual recording device of R, and the zoom is adjusted so that the imageof the signal display of T is large enough; “large enough” meaning forexample, that the image of the display screen is at least 75% of theentire image being captured by the visual recording device of R, andthat the image of the display screen is completely within the entireimage captured by the visual recording device of R (step 675). Followingthis step, the process goes back to step 355 and repeats the stepsthereon.

For device R to find the signal display of T, R's visual recordingdevice should try a variety of different viewing directions and viewingangles. Referring now to FIG. 7, a flow chart depicts an example of theprocess of step 671 of FIG. 6 in which a next viewing direction andangle size for device R is selected in an aspect of the presentinvention. As an illustration, for the current angle size <w,h> of thevisual recording device R, the current viewing direction of the visualrecording device is <p,t> (step 701). Here for example, w represents thewidth of the visual recording device angle size, h represents the heightof the visual recording device angle size; t (tilt) is the angle betweenthe vertical direction that is pointing up and the viewing direction ofthe visual recording device, and p (pan) is the counterclockwise anglebetween the north direction (on a dimensional plane) and the viewingdirection of the visual recording device. Next, it is determined whetherall possible viewing directions have been tried (step 715).

If all possible viewing directions have been tried, then a next viewingangle size <w*,h*> is chosen (step 755). It is then determined if allpossible viewing angle sizes have been tried (step 777). If yes, thenthe result is that an occlusion has been detected (795). If no, then anext viewing angle size <w*,h*> is tried, the viewing direction beingthe initial viewing direction <p,t> (step 779).

If all viewing directions have not been tried, then a next viewingdirection <p*,t*> is chosen (step 775). The angle size remains <w,h> andthe viewing direction is <p*,t*> (step 791).

In one aspect of the present invention, the angle size of the visualrecording device of R is automatically selected. Referring now to FIG.8, a flow chart depicts an example of the process of step 755 of FIG. 7in which a next viewing angle size for the visual recording device of Ris automatically selected. Initially, the visual recording device of Rdetermines an adequate size of a changing blob caused by the signaldisplay of T (step 801). This determination can be made “off-line,”meaning that this step can be performed individually without goingthrough the other steps in the process. For a largest angle size of thevisual recording device of R, an acceptance distance range N0 and F0between the visual recording device of R and the signal display of T isthen determined (step 815). The acceptance distance range is the rangein which the signal display of T can be identified and its encodedinformation analyzed; it is necessary to have an adequately sized viewof the signal display. N0 represents the nearest distance at which anadequately sized view of the signal display can be obtained, and F0represents the farthest distance at which an adequately sized view ofthe signal display can be obtained (“adequately sized” again meaning asize large enough such that the encoded information of the signaldisplay can be analyzed). To illustrate, for a given acceptance distancerange of the signal display of X for the visual recording device of Y,if x is outside this range then it will not be able to be detected bythe visual recording device of Y with a very high degree of certainty.For example, for a fixed visual recording device angle size of Y, if thesignal display of X is too close to Y, then the image of the display ofX might be too large to put into the image screen of the visualrecording device of Y. Thus, the distance between X and Y should belarge enough so that Y can get a good view of X (i.e., the image of thedisplay of X should not be too large). The acceptance distance range canbe calculated or experimentally obtained off line if the size of thesignal display of T is known.

Next, a candidate or the “i^(th)” angle size of the visual recordingdevice is determined (step 855). This can be automatically obtainedusing a formula that considers N0,F0, and the initial angle size of thevisual recording device. The object of this angle size selection processis to choose a set of angle sizes or zoom such that they can cover thewhole distance of the environment without overlap. To cover the wholedistance means that regardless of where T is, there will be one anglesize of R that can get an “adequately sized” view of T. For example, fora given distance from the signal display, it is desirable to choose asfew angle sizes (“zooms”) as possible which still enable the visualrecording device to get an adequately sized view of the signal display,i.e., “adequately sized view”, again meaning that the entire image ofthe signal display is visible and at a size large enough such that theencoded information of the signal display can be analyzed.

The following formulas can be used in selecting the i^(th) angle size ofthe visual recording device, where [w,h]=angle size and [w0,h0]represents an initial given angle size:${w\quad i} = {2\quad{\arctan\left\lbrack \frac{N_{0}}{F_{0}} \right\rbrack}^{i}{\tan\left( \frac{w_{0}}{2} \right)}}$${h\quad i} = {2\quad{\arctan\left\lbrack \frac{N_{0}}{F_{0}} \right\rbrack}^{i}{\tan\left( \frac{h_{0}}{2} \right)}}$In this way, we can get a set of angle sizes [w0,h0], [w1,h1], . . .[wq,hq].

The next angle size of the visual recording device is selected from thecandidate angle sizes obtained from the above formulas (step 875).

As shown in step 775 of FIG. 7, if all viewing directions of the visualrecording device of R have not been tried, a new viewing direction canbe selected. In one aspect of the present invention, a next viewingdirection can be automatically selected by R. Referring now to FIG. 9, aflow chart depicts a method of automatically selecting the viewingdirection, pan, and tilt of the visual recording device of R for a givencamera angle size [w,h].

For illustrative purposes, the first tilt selected is horizontal and thefirst pan can point in any direction P0 (step 900). The visual recordingdevice of R is panned clockwise in the amount p(t); this p(t) can be acalculated amount. If the new value p(t) passed the original value P0,then the value of the pan for the current tilt (horizontal) isexhausted; if the value p(t) did not pass P0, then p(t) will be the nextpan (step 901).

In step 905, it is determined whether all pan directions have beenexhausted. If yes, than it is then determined if the current tilt ishorizontal (step 915). If the current tilt is horizontal, the tilt ismoved up for h/2; this is the next tilt (step 951). If the current tiltis not horizontal, it is then determined if the tilt is above horizontal(step 950). If the current tilt is above horizontal, the next tilt willbe that which is below the horizontal and symmetrical to the currenttilt (step 955). If the current tilt is below the horizontal, in step971 a previous tilt that is symmetrical to the current tilt and abovethe horizontal is determined. The tilt is moved up for h/2 with respectto the previous tilt; if this tilt passes a vertical direction withrespect to the original horizontal position, then the tilt is exhausted.If this tilt does not pass the said vertical direction, than it will bethe next tilt value. It is then determined if the tilt is exhausted(step 975). In the case that the tilt is not exhausted, than step 901 isrepeated to select a next pan, and the process thereon is then repeated.If the tilt is exhausted, then the process goes back to step 791 (step976).

The following equation can be used as an example of how to calculate theamount p(t), where p represents a pan for a given tilt t (step 901):$2\quad\arctan\left\{ \frac{\sin\left( \frac{h}{2} \right)}{\sin\left( {t\frac{h}{2}} \right)} \right\}$

In order for the visual recording device of R to detect the signaldisplay of T, a method is employed in the present invention in which thesignal display of T alternates its display, for example, between blackand white, and an image difference is calculated for every consecutivealternating signal display image. The image differences are thenconverted into black or white images and the visual recording device ofR searches for and collects these alternating image difference “blobs”.A blob is a group of adjoining pixels each having an identical pixelvalue. Referring not to FIG. 10, a flow chart depicts an example of aprocess of step 657 of FIG. 6, in which device R identifies and verifiesan alternating image difference blob from the signal display of T.

First, device R asks the signal transmitting device T to alternate itssignal display between black and white within a certain period of time,for example 5 seconds (step 1001). Te visual recording device of R thencollects a number of images within an allotted time, for example, itcollects 5 images every 4.5 seconds (step 1001). An image differencebetween each of the 5 consecutive images is then calculated; the resulthere would be 4 image differences (step 1015). To illustrate the processof calculating the image difference, for a given black and white imagewith resolution of 100×100 (having a total of 10,000 pixels), each pixelis identified by a coordinate (x,y), where 1<x<100 and 1<y<100. Eachcoordinate (x,y) also has an intensity value between 0-255, where, forinstance, a value of 0 means the pixel is black and a value of 255 meansthe pixel is white. For example, the center pixel of the image, 50×50,may have an image intensity of 0. The center pixel [50,50] for anotherimage may have an image intensity of 255. Therefore, the differencebetween the center pixels of the two images in this example is 255. Fortwo images A and B, the image difference will be image C, where theintensities of any pixels of C will be the difference of the intensitiesof corresponding pixels of A and B.

If the images collected by the visual recording device are in color,then the image differences will also be in color. In this case, thepixel coordinate (x,y) has 3 component values for each of the colorsred, green and blue, e.g., (r,g,b). Each of the colors red, green andblue has an intensity range of 0-255, For any coordinate (x,y), theimage difference for two images at (x,y) will be (|r₁−r₂|, |g₁−g₂|,|b₁−b₂|). The resulting image C is still a color image, where (r,g,b) isthe intensity for (x,y) at the first image and (r₂,g₂,b₂) is theintensity for (x,y) at the second image.

These color images are then changed into black and white images based onthe intensity value for each pixel (step 1055). For example, it can bespecified that when the image difference is greater than 55, the pixelis given a color of white; otherwise, it is black.

For example to illustrate, if:√{square root over ((r₁−r₂)²+(g₁−g₂)²+(b₁−b₂)²)}is ≦55, the intensity at (x,y) for the difference image is 0; otherwiseit is 255. The alternating image differences or changing blobs are thencollected, and the changing blob having the largest area is the image ofthe signal display of T (step 1075).

FIG. 11 is the encoding stategy determination process for signaltransmitting device T in one aspect of the present invention, asdepicted in step 255 of FIG. 2. For illustrative purposes, theresolution of the display device of T is set to 50×50. This is denotedit as: A[50][50] (step 1101). Next, the horizontal and vertical valuesof A[50][50] are divided by 10. The result is A[5][5], which has a totalof 25 individual blocks 1202, as illustrated in FIG. 12. In thisexample, the intensity values of the pixels within each block are thesame; they are either (255,255,255) or (0,0,0) (step 1105). Since eachblock has, for example, 2 different values here, black or white, thetotal information that can be encoded by the signal display is 2²⁵ (step1115). Next, the information to be transmitted is assigned to one of thepatterns represented by A[50][50] (step 1155). The pattern for theassigned information is then displayed (step 1160).

Referring now to FIG. 13, a flow chart depicts an example of a method ofbuilding a position an radius look-up table in one aspect of the presentinvention. This flow chart is an example of a detailed method ofdetermining the signal decoding mechanism of device R, as depicted instep 355. Initially, a block is selected from the signal display of T(step 1301). The intensity of the other blocks of the signal display ofT are kept constant, while the intensity of the selected block isalternated (step 1305). The visual recording device of device R thengrabs the images and uses the changing blob detection method (describedin FIG. 10) to detect the blocks whose intensities are being alternated(step 1315). The center of the “changing blob” or alternating image, isfound, and a circle is drawn around the blob such that all the pixelswithin the circle belong to the blob (step 1355). The center of thecircle will be the center for the block in which it resides, and theradius of the circle will be the radius recorded in the position andradius look-up table. FIG. 14 depicts an exemplary illustration of theposition and radius look-up table. In one preferred embodiment of thepresent invention, the radius of the circles should be no more than 0.35of the length of one block.

FIG. 15 is a flow chart depicting an example of a visual communicationprocess for device T and device R as shown in steps 275 and 375according to one aspect of the present invention. Initially, signaltransmitting device T determines a signal S to be transmitted (step1501). Device T then encodes the signal S into a two-dimensional patternmatrix I[m,n](r,g,b), where I=intensity, [m,n] represents the positionof a pixel, and (r,g,b) represents red, green and blue respectively.(step 1505). Device T then displays the information presented byI[m,n](r,g,b) (step 1515). Next, signal receiving device R takes animage of the information displayed by device T (step 1555). In step1575, device R then decodes the signal by analyzing the image taken bythe visual recording device of R.

Referring now to FIG. 16, a flow chart depicts an example of a visualcommunication signal decoding process of device R as discussed in step1575 of FIG. 15. In an illustrative example, the visual recording deviceof R takes an image B[w,h] which contains a displayed graphic userinterface (GUI) from device T. The variables [w,h] represent width andheight, respectively. As an example, the width and height of imageB[w,h] is 150×150 (step 1601). Device R then determines the positions ofthe centers of the images of all the blocks of the display of device Twith the position and radius look-up table (step 1605). Circles are thendrawn centered at the centers determined in step 1605 above; the radiusof these circles should be read from the position and radius look-uptable (step 1615).

For each circle, device R calculates the average image intensities amongeach pixel within the circle. The average image intensity is thencalculated for every circle. These average intensities are taken as theaverage intensities of their respective blocks (step 1655). Device Rthen changes the average intensities of all the blocks into black andwhite intensities, each represented by (b_w_i). If a b_w_i is less thana certain amount, for example 50, it can be determined that the originalblock is encoded as black; otherwise, it is encoded as white (step1675). The signal S transmitted from T is then decoded by device R bydecoding the above black and white pattern formed in step 1675 (step1695).

FIG. 17 depicts an exemplary illustration of step 1655, in which 1701represents an entire view seen by the visual recording device R. 1705depicts an exemplary image of the display screen of T, and the greyscale blocks 1710 depict blocks with their respective calculated averageimage intensities as discussed in step 1655.

FIG. 18 depicts an exemplary illustration of step 1675, in which theaverage intensities of all the blocks is converted into black or whiteintensities. For example, blocks 1701 from FIG. 17 were changed to blackhere (1801), from greyscale in FIG. 17, since their b_w_i was less than50.

In one embodiment of the present invention, embedded devices can bedevised in which existing radio frequency communication technologycoexists with the communication system of the present invention. Forexample, an embedded device can use existing technology, e.g., spreadspectrum, to make the initial contact with another embedded device, andwhen lack of occlusion has been determined between the embedded devices,they can then switch over to communication using visual images asdescribed in the present invention. In another example, embedded devicesmay employ existing wireless communication technology when transmittingespecially large amounts of data, but can then switch back to using thecommunication system of the present invention when transmitting smalleramounts of data. Advantageously, this reduces the overall amount ofradiation a user is exposed to.

It is to be appreciated by those of ordinary skill in the atr that thepresent invention may preferably employ mirrors to enable communicationamong embedded devices around occlusions or obstructions. In anotherembodiment of the present invention, embedded devices may transmitsignals around moving obstructions, such as people walking around a roomin the signal path of embedded devices.

In another embodiment of the present invention, an embedded device, forexample a computer, can have both a signal transmitting device and asignal receiving device.

Although illustrative embodiments of the present invention have beendescribed herein with reference to the accompanying drawings, it is tobe understood that the present invention is not limited to those preciseembodiments, and that various other changes and modifications may beaffected therein by one skilled in the art without departing from thescope or spirit of the invention. All such changes and modifications areintended to be included within the scope of the invention as defined bythe appended claims.

1. A communication system comprising: a signal transmitting device having a sending CPU and a sending memory; a generated signal template for generating a signal pattern to be transmitted; a signal display for displaying the signal pattern generated by said generated signal template; a signal display controller for controlling position and orientation of said signal display; a signal receiving device for communicating with said signal transmitting device having a receiving memory and a receiving CPU; a visual recording device for sensing the signal pattern of the signal display; an image for decoding the signal pattern; and a visual recording device controller for automatically controlling the orientation and zoom of said visual recording device, wherein communication between said signal transmitting device and said signal receiving device is established by the visual recording device detecting and decoding visual images displayed by the signal display.
 2. The system of claim 1, wherein a plurality of mirrors are used to transmit signal patterns between a signal transmitting device and a signal receiving device having obstructions between them.
 3. A signal transmitting device comprising: a sending CPU and a sending memory; a generated signal template for generating a signal pattern to be transmitted, wherein the signal pattern is a visual pattern of blobs; a signal display for displaying the signal pattern generated by said generated signal template; and a signal display controller for controlling a position and an orientation of said signal display relative to a signal receiving device, wherein the signal pattern is visible to the signal receiving device.
 4. The signal transmitting device of claim 3, wherein each blob is a plurality of adjoining pixels each having an identical pixel value, wherein a pixel value is selected from the group consisting of black and white.
 5. A signal receiving device comprising: a receiving memory and a receiving CPU; a visual recording device for determining a signal pattern of a signal display, wherein the signal pattern is a visual pattern of blobs; an image decoder for decoding the signal pattern; and a visual recording device controller for automatically controlling the orientation and zoom of said visual recording device, wherein communication between a signal transmitting device comprising the signal display and the signal receiving device is established by the visual recording device detecting and decoding the signal pattern displayed by the signal display.
 6. The signal receiving device of claim 5, wherein each blob is a plurality of adjoining pixels each having an identical pixel value, wherein a pixel value is selected from the group consisting of black and white. 